LCOV - code coverage report
Current view: top level - imageanalysis/ImageAnalysis - SpectralFitter.cc (source / functions) Hit Total Coverage
Test: casacpp_coverage.info Lines: 0 270 0.0 %
Date: 2024-10-10 15:00:01 Functions: 0 10 0.0 %

          Line data    Source code
       1             : //# SpectralCollapser.cc: Implementation of class SpectralCollapser
       2             : //# Copyright (C) 1998,1999,2000,2001,2003
       3             : //# Associated Universities, Inc. Washington DC, USA.
       4             : //#
       5             : //# This program is free software; you can redistribute it and/or modify it
       6             : //# under the terms of the GNU General Public License as published by the Free
       7             : //# Software Foundation; either version 2 of the License, or (at your option)
       8             : //# any later version.
       9             : //#
      10             : //# This program is distributed in the hope that it will be useful, but WITHOUT
      11             : //# ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
      12             : //# FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License for
      13             : //# more details.
      14             : //#
      15             : //# You should have received a copy of the GNU General Public License along
      16             : //# with this program; if not, write to the Free Software Foundation, Inc.,
      17             : //# 675 Massachusetts Ave, Cambridge, MA 02139, USA.
      18             : //#
      19             : //# Correspondence concerning AIPS++ should be addressed as follows:
      20             : //#        Internet email: casa-feedback@nrao.edu.
      21             : //#        Postal address: AIPS++ Project Office
      22             : //#                        National Radio Astronomy Observatory
      23             : //#                        520 Edgemont Road
      24             : //#                        Charlottesville, VA 22903-2475 USA
      25             : //#
      26             : //# $Id: $
      27             : 
      28             : #include <imageanalysis/ImageAnalysis/SpectralFitter.h>
      29             : #include <casacore/casa/Arrays/ArrayMath.h>
      30             : #include <casacore/casa/OS/Directory.h>
      31             : #include <casacore/casa/OS/RegularFile.h>
      32             : #include <casacore/casa/OS/SymLink.h>
      33             : #include <casacore/coordinates/Coordinates/SpectralCoordinate.h>
      34             : //#include <imageanalysis/ImageAnalysis/ImageFit1D.h>
      35             : #include <casacore/images/Images/ImageUtilities.h>
      36             : #include <imageanalysis/ImageAnalysis/ImageMoments.h>
      37             : #include <casacore/images/Images/FITSImage.h>
      38             : #include <casacore/images/Images/FITSQualityImage.h>
      39             : #include <casacore/images/Images/MIRIADImage.h>
      40             : #include <casacore/images/Images/PagedImage.h>
      41             : #include <casacore/images/Images/SubImage.h>
      42             : #include <casacore/images/Images/TempImage.h>
      43             : #include <components/SpectralComponents/SpectralList.h>
      44             : #include <components/SpectralComponents/SpectralElement.h>
      45             : #include <components/SpectralComponents/ProfileFit1D.h>
      46             : #include <casacore/lattices/Lattices/LatticeUtilities.h>
      47             : 
      48             : using namespace casacore;
      49             : namespace casa {
      50           0 : SpectralFitter::SpectralFitter():
      51           0 :         _log(new LogIO()), _resultMsg(""){
      52           0 :         _setUp();
      53           0 : }
      54             : 
      55           0 : SpectralFitter::~SpectralFitter() {
      56           0 :         delete _log;
      57           0 : }
      58             : 
      59           0 : Bool SpectralFitter::fit(const Vector<Float> &spcVals,
      60             :                 const Vector<Float> &yVals, const Vector<Float> &eVals,
      61             :                 const Float startVal, const Float endVal,
      62             :                 const Bool fitGauss, const Bool fitPoly,
      63             :                 const uInt nPoly, String &msg) {
      64             : 
      65           0 :         *_log << LogOrigin("SpectralFitter", "fit", WHERE);
      66           0 :         _fitStatus=SpectralFitter::UNKNOWN;
      67             : 
      68           0 :         if (spcVals.size() < 1) {
      69           0 :                 msg = String("No spectral values provided!");
      70           0 :                 *_log << LogIO::WARN << msg << LogIO::POST;
      71           0 :                 return false;
      72             :         }
      73             : 
      74           0 :         Bool ascending = true;
      75           0 :         if (spcVals(spcVals.size() - 1) < spcVals(0))
      76           0 :                 ascending = false;
      77             : 
      78             :         uInt startIndex, endIndex;
      79           0 :         if (ascending) {
      80           0 :                 if (endVal < spcVals(0)) {
      81           0 :                         msg = String("Start value: ") + String::toString(endVal) + String(
      82           0 :                                         " is smaller than all spectral values!");
      83           0 :                         *_log << LogIO::WARN << msg << LogIO::POST;
      84           0 :                         return false;
      85             :                 }
      86           0 :                 if (startVal > spcVals(spcVals.size() - 1)) {
      87           0 :                         msg = String("End value: ") + String::toString(startVal) + String(
      88           0 :                                         " is larger than all spectral values!");
      89           0 :                         *_log << LogIO::WARN << msg << LogIO::POST;
      90           0 :                         return false;
      91             :                 }
      92           0 :                 startIndex = 0;
      93           0 :                 while (spcVals(startIndex) < startVal)
      94           0 :                         startIndex++;
      95             : 
      96           0 :                 endIndex = spcVals.size() - 1;
      97           0 :                 while (spcVals(endIndex) > endVal)
      98           0 :                         endIndex--;
      99             :         } else {
     100           0 :                 if (endVal < spcVals(spcVals.size() - 1)) {
     101           0 :                         msg = String("Start value: ") + String::toString(endVal) + String(
     102           0 :                                         " is smaller than all spectral values!");
     103           0 :                         *_log << LogIO::WARN << msg << LogIO::POST;
     104           0 :                         return false;
     105             :                 }
     106           0 :                 if (startVal > spcVals(0)) {
     107           0 :                         msg = String("End value: ") + String::toString(startVal) + String(
     108           0 :                                         " is larger than all spectral values!");
     109           0 :                         *_log << LogIO::WARN << msg << LogIO::POST;
     110           0 :                         return false;
     111             :                 }
     112           0 :                 startIndex = 0;
     113           0 :                 while (spcVals(startIndex) > endVal)
     114           0 :                         startIndex++;
     115             : 
     116           0 :                 endIndex = spcVals.size() - 1;
     117           0 :                 while (spcVals(endIndex) < startVal)
     118           0 :                         endIndex--;
     119             :         }
     120             : 
     121             :         // prepare the fit images
     122           0 :         Vector<Bool> maskVals;
     123           0 :         Vector<Double> weightVals;
     124           0 :         if (!_prepareData(spcVals, eVals, startIndex, endIndex, maskVals, weightVals)){
     125           0 :                 msg = String("The error array contains values <0.0!");
     126           0 :                 *_log << LogIO::WARN << msg << LogIO::POST;
     127           0 :                 return false;
     128             :         }
     129             : 
     130             :         // make sure that something can be done
     131           0 :         if ((endIndex-startIndex) + 1 < 2){
     132           0 :                 msg = String("Only one data value selected. Can not fit anything.");
     133           0 :                 *_log << LogIO::WARN << msg << LogIO::POST;
     134           0 :                 return false;
     135             :         }
     136           0 :         else if (fitGauss && ((endIndex-startIndex) + 1 < 3)){
     137           0 :                 msg = String("Only two data value selected. Can not fit a Gaussian.");
     138           0 :                 *_log << LogIO::WARN << msg << LogIO::POST;
     139           0 :                 return false;
     140             :         }
     141             : 
     142             :         // convert the input values to Double
     143           0 :         Vector<Double> dspcVals(spcVals.size()), dyVals(yVals.size());
     144           0 :         convertArray(dspcVals,  spcVals);
     145           0 :         convertArray(dyVals,    yVals);
     146             : 
     147             : 
     148             :         // store start and end values
     149           0 :         _startVal   = startVal;
     150           0 :         _endVal     = endVal;
     151           0 :         _startIndex = startIndex;
     152           0 :         _endIndex   = endIndex;
     153             : 
     154             :         // set data, weights and status
     155           0 :         _fit.clearList();
     156           0 :         if (weightVals.size()>0){
     157           0 :                 _fit.setData (dspcVals, dyVals, maskVals, weightVals);
     158             :         }
     159             :         else {
     160           0 :                 _fit.setData (dspcVals, dyVals, maskVals);
     161             :         }
     162             : 
     163             :         // set the estimated elements
     164           0 :         SpectralList elemList;
     165           0 :         _prepareElems(fitGauss, fitPoly, nPoly, dspcVals, dyVals, elemList);
     166           0 :         _fit.setElements(elemList);
     167             :         //_report(_fit.getList(false), *_log);
     168             : 
     169             :         // do the fit
     170           0 :         Bool ok(false);
     171             :         try {
     172           0 :                 ok = _fit.fit();
     173           0 :         } catch (AipsError& x) {
     174           0 :                 msg = x.getMesg();
     175           0 :                 *_log << LogIO::WARN << msg << LogIO::POST;
     176           0 :                 return false;
     177           0 :         }
     178           0 :         if (ok){
     179           0 :                 _fitStatus=SpectralFitter::SUCCESS;
     180             :         }
     181             :         else{
     182           0 :                 _fitStatus=SpectralFitter::FAILED;
     183           0 :            msg = "Fitter did not converge in " + String::toString(_fit.getNumberIterations()) + " iterations";
     184           0 :            *_log << LogIO::NORMAL  << msg << LogIO::POST;
     185           0 :            return false;
     186             :         }
     187             : 
     188           0 :         return true;
     189           0 : }
     190             : 
     191           0 : void SpectralFitter::getFit(const Vector<Float> &spcVals, Vector<Float> &spcFit, Vector<Float> &yFit) const{
     192           0 :         Vector<Double> tmp;
     193             : 
     194             :         // re-size all vectors
     195           0 :         spcFit.resize(_endIndex-_startIndex+1);
     196           0 :         yFit.resize(_endIndex-_startIndex+1);
     197           0 :         tmp.resize(_endIndex-_startIndex+1);
     198             : 
     199             :         // extract the range of the independent coordinate
     200           0 :         spcFit = spcVals(IPosition(1, _startIndex), IPosition(1, _endIndex));
     201             : 
     202             :         // extract the range of the dependent coordinate
     203           0 :         tmp    = (getFit())(IPosition(1, _startIndex), IPosition(1, _endIndex));
     204             : 
     205             :         // convert to Float
     206           0 :         convertArray(yFit, tmp);
     207           0 : }
     208             : 
     209           0 : String SpectralFitter::report(LogIO &os, const String &xUnit, const String &yUnit, const String &yPrefixUnit) const{
     210           0 :         String resultMsg("");
     211           0 :         SpectralList list = _fit.getList(true);
     212             : 
     213           0 :         switch (_fitStatus){
     214           0 :         case SpectralFitter::SUCCESS:
     215           0 :                 os << LogIO::NORMAL << " " << LogIO::POST;
     216           0 :                 os << LogIO::NORMAL << "Successful fit!" << LogIO::POST;
     217           0 :                 os << LogIO::NORMAL << "No. of iterations: " << String::toString(_fit.getNumberIterations()) << LogIO::POST;
     218           0 :                 os << LogIO::NORMAL << "Chi-square:       " << String::toString(_fit.getChiSquared())       << LogIO::POST;
     219             :                 // report the spectral elements
     220           0 :                 resultMsg  = _report(os, list, xUnit, yUnit, yPrefixUnit);
     221             : 
     222           0 :                 break;
     223           0 :         case SpectralFitter::FAILED:
     224           0 :                 resultMsg = "Fit did not converge in " + String::toString(_fit.getNumberIterations()) + " iterations!";
     225           0 :                 os << LogIO::NORMAL << " " << LogIO::POST;
     226           0 :                 os << LogIO::NORMAL << resultMsg << LogIO::POST;
     227           0 :                 break;
     228           0 :         default:
     229           0 :                 resultMsg = "The fit is in an undefined state!";
     230           0 :                 os << LogIO::NORMAL << " " << LogIO::POST;
     231           0 :                 os << LogIO::NORMAL << resultMsg << LogIO::POST;
     232             :         }
     233             : 
     234           0 :         return resultMsg;
     235           0 : }
     236             : 
     237           0 : void SpectralFitter::_setUp() {
     238           0 :         *_log << LogOrigin("SpectralFitter", "setUp");
     239             : 
     240             :         // setup the fitter and the status
     241           0 :         _fit = ProfileFit1D<Double>();
     242           0 :         _fitStatus=SpectralFitter::UNKNOWN;
     243           0 : }
     244             : 
     245           0 : Bool SpectralFitter::_prepareData(const Vector<Float> &xVals, const Vector<Float> &eVals,
     246             :                 const Int &startIndex, const Int &endIndex, Vector<Bool> &maskVals, Vector<Double> &weightVals) const {
     247             : 
     248             :         // create the mask
     249           0 :         maskVals.resize(xVals.size());
     250           0 :         maskVals = false;
     251           0 :         maskVals(IPosition(1, startIndex), IPosition(1, endIndex)) = true;
     252             : 
     253             :         // if possible, compute the weights
     254           0 :         if (eVals.size()>0){
     255           0 :                 weightVals.resize(xVals.size());
     256           0 :                 weightVals=0.0;
     257           0 :                 Vector<Double> one(eVals.size(), 1.0);
     258           0 :                 Vector<Double> deVals(eVals.size(), 0.0);
     259           0 :                 convertArray(deVals, eVals);
     260             : 
     261             :                 // find the minimum of the error values
     262           0 :                 Double minVal=min(eVals(IPosition(1, startIndex), IPosition(1, endIndex)));
     263             : 
     264             :                 // a value smaller zero make no sense
     265           0 :                 if (minVal<0.0){
     266           0 :                         return false;
     267             :                 }
     268             :                 // if the error is zero, discard all errors
     269           0 :                 else if (minVal==0.0){
     270           0 :                         String msg = String("The error array contains values=0.0 ==> ALL error values are discarded!");
     271           0 :                         *_log << LogIO::WARN << msg << LogIO::POST;
     272           0 :                         weightVals.resize(0);
     273           0 :                 }
     274             :                 // compute the weights
     275             :                 else {
     276           0 :                         weightVals(IPosition(1, startIndex), IPosition(1, endIndex)) = one(IPosition(1, startIndex), IPosition(1, endIndex)) / deVals(IPosition(1, startIndex), IPosition(1, endIndex));
     277             :                 }
     278           0 :         }
     279           0 :         return true;
     280             : }
     281             : 
     282           0 : Bool SpectralFitter::_prepareElems(const Bool fitGauss, const Bool fitPoly, const uInt nPoly, Vector<Double> &xVals,
     283             :                 Vector<Double> &yVals, SpectralList& list){
     284           0 :         Int nQuart=max(1,Int((_endIndex-_startIndex)/4));
     285             : 
     286           0 :         Double leftYVal(0.0), rightYVal(0.0);
     287           0 :         Double leftXVal(0.0), rightXVal(0.0);
     288           0 :         for (uInt index=_startIndex; index < (_startIndex+nQuart); index++){
     289           0 :                 leftXVal += xVals(index);
     290           0 :                 leftYVal += yVals(index);
     291             :         }
     292           0 :         leftXVal /= Double(nQuart);
     293           0 :         leftYVal /= Double(nQuart);
     294             : 
     295           0 :         for (uInt index=_endIndex; index > (_endIndex-nQuart); index--){
     296           0 :                 rightXVal += xVals(index);
     297           0 :                 rightYVal += yVals(index);
     298             :         }
     299           0 :         rightXVal /= Double(nQuart);
     300           0 :         rightYVal /= Double(nQuart);
     301             : 
     302             :         // make sure that the wavelength
     303             :         // is 'ascending'
     304           0 :         if (xVals(_startIndex)>xVals(_endIndex)){
     305             :                 Double tmp;
     306           0 :                 tmp       = leftXVal;
     307           0 :                 leftXVal  = rightXVal;
     308           0 :                 rightXVal = tmp;
     309             : 
     310           0 :                 tmp       = leftYVal;
     311           0 :                 leftYVal  = rightYVal;
     312           0 :                 rightYVal = tmp;
     313             :         }
     314             : 
     315             :         // estimate the parameters
     316             :         // of the polynomial and add it
     317           0 :         if (fitPoly) {
     318           0 :                 if (nPoly==0){
     319           0 :                         Vector<Double> pPar(1, 0.5*(rightYVal+leftYVal));
     320           0 :                         list.add(PolynomialSpectralElement(pPar));
     321           0 :                 }
     322           0 :                 else if (nPoly==1){
     323           0 :                         Vector<Double> pPar(2, 0.0);
     324           0 :                         pPar(1) = (rightYVal-leftYVal) / (rightXVal-leftXVal);
     325           0 :                         pPar(0) = rightYVal - pPar(1)*rightXVal;
     326           0 :                         list.add(PolynomialSpectralElement(pPar));
     327           0 :                 }
     328             :         }
     329             : 
     330             :         // estimate the parameters
     331             :         // of the Gaussian and add it
     332           0 :         if (fitGauss){
     333           0 :                 Double gAmp(0.0), gCentre(0.0), gSigma(0.0);
     334             : 
     335             :                 // integrate over the data
     336           0 :                 Double curveIntegral(0.0), polyIntegral(0.0), averDisp(0.0);
     337           0 :                 for (uInt index=_startIndex; index < (_endIndex+1); index++)
     338           0 :                         curveIntegral += yVals(index);
     339             : 
     340             :                 // integrate over the estimated polynomial
     341           0 :                 polyIntegral   = 0.5*(rightYVal+leftYVal)*Double(_endIndex-_startIndex+1);
     342             : 
     343             :                 // compute the average dispersion
     344           0 :                 averDisp = fabs(xVals(_endIndex) - xVals(_startIndex)) /  Double(_endIndex-_startIndex);
     345             : 
     346             :                 // make an estimate for the sigma (FWHM ~1/4 of x-range);
     347             :                 // get the amplitude estimate from the integral and the sigma;
     348             :                 // the centre estimate is set to the middle of the x-range;
     349           0 :                 gSigma = (xVals(_startIndex+nQuart)-xVals(_endIndex-nQuart))/(2.0*GaussianSpectralElement::SigmaToFWHM);
     350           0 :                 if (gSigma<0.0)
     351           0 :                         gSigma *= -1.0;
     352           0 :                 gAmp = averDisp*(curveIntegral-polyIntegral)/(gSigma*sqrt(2.0*C::pi));
     353           0 :                 gCentre = xVals(_startIndex) + (xVals(_endIndex) - xVals(_startIndex)) / 2.0;
     354             : 
     355             :                 // add the Gaussian element
     356           0 :                 list.add(GaussianSpectralElement(gAmp, gCentre, gSigma));
     357             :         }
     358             : 
     359           0 :         return true;
     360             : }
     361             : 
     362           0 : String SpectralFitter::_report(LogIO &os, const SpectralList &list, const String &xUnit, const String &yUnit, const String &yPrefixUnit) const{
     363           0 :         ostringstream sstream;
     364             : 
     365           0 :         String spTypeStr;
     366           0 :         String intUnit(""), slopeUnit(""), xStreamUnit(""), yStreamUnit("");
     367             :         //Vector<Double> params, errors;
     368           0 :         Double gaussAmpV(0.0), gaussCentV(0.0), gaussSigmaV(0.0), gaussFWHMV(0.0);
     369           0 :         Double gaussAmpE(0.0), gaussCentE(0.0), gaussSigmaE(0.0), gaussFWHME(0.0);
     370           0 :         Double gaussAreaV(0.0), gaussAreaE(0.0);
     371           0 :         Double polyOffsetV(0.0), polySlopeV(0.0);
     372           0 :         Double polyOffsetE(0.0), polySlopeE(0.0);
     373           0 :         Int gaussIndex(-1), polyIndex(-1);
     374             : 
     375             :         // compose the unit for the Gauss integral
     376           0 :         if (xUnit.size()>0 && yUnit.size()>0) {
     377           0 :                 intUnit = String(" [")+yPrefixUnit+yUnit+String("*")+xUnit+String("]");
     378           0 :                 if (xUnit.contains("/"))
     379           0 :                         slopeUnit = String(" [")+yPrefixUnit+yUnit+String("/(")+xUnit+String(")]");
     380             :                 else
     381           0 :                         slopeUnit = String(" [")+yPrefixUnit+yUnit+String("/")+xUnit+String("]");
     382             :         }
     383             : 
     384             :         // compose the units for the fit
     385             :         // values on the x-axis
     386           0 :         if (xUnit.size()>0)
     387           0 :                 xStreamUnit = String(" [")+xUnit+String("]");
     388             : 
     389             :         // compose the units for the fit
     390             :         // values on the y-axis
     391           0 :         if (yUnit.size()>0)
     392           0 :                 yStreamUnit = String(" [")+ yPrefixUnit + yUnit+String("]");
     393           0 :         else if (yPrefixUnit.size()>0)
     394           0 :                 yStreamUnit = String(" (")+yPrefixUnit+String(")");
     395             : 
     396             :         // go over all elements
     397           0 :         for (uInt index=0; index < list.nelements(); index++){
     398             : 
     399             :                 // report element type and get the parameters/errors
     400           0 :                 SpectralElement::Types spType = list[index]->getType();
     401           0 :                 spTypeStr = list[index]->fromType(spType);
     402             :                 //returnMsg += spTypeStr;
     403             :                 //os << LogIO::NORMAL << "Element No. " << String::toString(index) << ": " << spTypeStr << LogIO::POST;
     404           0 :                 Vector<Double> params = list[index]->get();
     405             :                 //list[index]->getError(errors);
     406           0 :                 Vector<Double> errors = list[index]->getError();
     407             : 
     408           0 :                 switch (spType){
     409             : 
     410             :                 // extract and report the Gaussian parameters
     411           0 :                 case SpectralElement::GAUSSIAN:
     412           0 :                         gaussIndex  = index;
     413           0 :                         gaussAmpV   = params(0);
     414           0 :                         gaussCentV  = params(1);
     415           0 :                         gaussSigmaV = params(2);
     416           0 :                         gaussFWHMV  = gaussSigmaV * GaussianSpectralElement::SigmaToFWHM;
     417           0 :                         gaussAreaV  = gaussAmpV * gaussSigmaV * sqrt(2.0*C::pi);
     418           0 :                         gaussAmpE   = errors(0);
     419           0 :                         gaussCentE  = errors(1);
     420           0 :                         gaussSigmaE = errors(2);
     421           0 :                         gaussFWHME  = gaussSigmaE * GaussianSpectralElement::SigmaToFWHM;
     422           0 :                         gaussAreaE  = sqrt(C::pi) * sqrt(gaussAmpV*gaussAmpV*gaussSigmaE*gaussSigmaE + gaussSigmaV*gaussSigmaV*gaussAmpE*gaussAmpE);
     423             : 
     424             :                         //os << LogIO::NORMAL << "  Amplitude: " << String::toString(gaussAmpV) << "+-" << gaussAmpE << yStreamUnit << " centre: " << String::toString(gaussCentV) << "+-" << gaussCentE << xStreamUnit << " FWHM: " << String::toString(gaussFWHMV) << "+-" << gaussFWHME << xStreamUnit << LogIO::POST;
     425           0 :                         os << LogIO::NORMAL << "  Gauss amplitude: " << String::toString(gaussAmpV) << "+-" << gaussAmpE << yStreamUnit << LogIO::POST;
     426           0 :                         os << LogIO::NORMAL << "  Gauss centre:    " << String::toString(gaussCentV) << "+-" << gaussCentE << xStreamUnit << LogIO::POST;
     427           0 :                         os << LogIO::NORMAL << "  Gauss FWHM:      " << String::toString(gaussFWHMV) << "+-" << gaussFWHME << xStreamUnit << LogIO::POST;
     428           0 :                         os << LogIO::NORMAL << "  Gaussian area:   " << String::toString(gaussAreaV) <<"+-"<< gaussAreaE << intUnit << LogIO::POST;
     429             :                         //returnMsg += " Cent.: " + String::toString(gaussCentV) + " FWHM: " + String::toString(gaussFWHMV) + "  Ampl.: " + String::toString(gaussAmpV);
     430           0 :                         sstream << " Cent.: " << setiosflags(ios::scientific) << setprecision(6) << gaussCentV << " FWHM: " << setprecision(4) << gaussFWHMV << "  Ampl.: " << setprecision(3) << gaussAmpV;
     431           0 :                         break;
     432             : 
     433             :                 // extract and report the polynomial parameters
     434           0 :                 case SpectralElement::POLYNOMIAL:
     435           0 :                         polyIndex  = index;
     436           0 :                         polyOffsetV = params(0);
     437           0 :                         polyOffsetE = errors(0);
     438           0 :                         if (params.size()>1){
     439           0 :                                 polySlopeV = params(1);
     440           0 :                                 polySlopeE = errors(2);
     441             :                         }
     442           0 :                         os << LogIO::NORMAL << "  Offset: " << String::toString(polyOffsetV) << "+-"<< String::toString(polyOffsetE) << yStreamUnit <<LogIO::POST;
     443             :                         //returnMsg += "  Offs.: " + String::toString(polyOffsetV);
     444           0 :                         sstream << "  Offs.: " << setiosflags(ios::scientific) << setprecision(3) << polyOffsetV;
     445           0 :                         if (params.size()>1){
     446           0 :                                 os << LogIO::NORMAL << "  Slope:  " << String::toString(polySlopeV) << "+-"<< String::toString(polySlopeE) << slopeUnit << LogIO::POST;
     447           0 :                                 sstream << "  Slope:  " << setiosflags(ios::scientific) << setprecision(3) << polySlopeV;
     448             :                                 //returnMsg += "  Slope:  " + String::toString(polySlopeV);
     449             :                         }
     450           0 :                         break;
     451             : 
     452             :                 // report the parameters
     453           0 :                 default:
     454           0 :                         os << LogIO::NORMAL << "  parameters: " << String::toString(params) << LogIO::POST;
     455           0 :                         os << LogIO::NORMAL << "  errors:     " << String::toString(errors) << LogIO::POST;
     456             :                         //returnMsg += "  Params:  " + String::toString(params);
     457           0 :                         sstream << "  Params:  " << params;
     458           0 :                         break;
     459             :                 }
     460           0 :         }
     461             : 
     462             :         // if possible, compute and report the equivalent width
     463           0 :         if (gaussIndex > -1 && polyIndex >- 1){
     464           0 :                 Double centVal = (*list[polyIndex])(gaussCentV);
     465           0 :                 if (centVal==0.0){
     466           0 :                         sstream << LogIO::NORMAL << "  Continuum is 0.0 - can not compute equivalent width!" << LogIO::POST;
     467             :                 }
     468             :                 else{
     469           0 :                         os << LogIO::NORMAL << "Can compute equivalent width" << LogIO::POST;
     470           0 :                         os << LogIO::NORMAL << "  Continuum value: " << String::toString(centVal) << yStreamUnit << LogIO::POST;
     471           0 :                         os << LogIO::NORMAL << "  --> Equivalent width: " << String::toString(-1.0*gaussAreaV/centVal) << xStreamUnit << LogIO::POST;
     472           0 :                         sstream << " Equ.Width: " << setiosflags(ios::scientific) << setprecision(4) << -1.0*gaussAreaV/centVal;
     473             :                         //returnMsg += " Equ.Width: "+ String::toString(-1.0*gaussAreaV/centVal);
     474             :                 }
     475             :         }
     476           0 :         return String(sstream);
     477           0 : }
     478             : }
     479             : 

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